CN110880225A - Residual current type electric fire intelligent monitoring analysis method and device - Google Patents

Abstract

The invention discloses a residual current type electric fire intelligent monitoring analysis method and a device, wherein the method comprises the following steps: according to the obtained residual current value, the acquisition time and the loop characteristic identification of the monitored loop, intelligently analyzing the residual current value exceeding the alarm threshold and the monitored loop, judging whether the alarm loop meets the common zero, the motor starting impact load and the loop inherent leakage current characteristic, if the alarm loop meets any one of the characteristics, generating updated alarm fault information and prompting the root cause of the problem; the system provided with the multi-stage residual current type electrical fire detector also has the function of judging the position information of the fault point.

Description

Residual current type electric fire intelligent monitoring analysis method and device

Technical Field

The invention relates to the field of intelligent monitoring of electrical fires, in particular to a residual current type analysis method and a residual current type analysis device for intelligent monitoring of electrical fires.

Background

At present, the domestic detection of the residual current adopts a conventional method, the data acquisition of the residual current is realized based on an electric fire monitoring host and a downstream detector, the data acquisition is uploaded to a monitoring center through a wireless gateway, the remote monitoring of the residual current of a power line is realized, the variation trend of the residual current in the power line is analyzed according to the conventional method, and the threshold value alarming function is realized. However, the prior art has the following defects:

there is a lack of alarm analysis. An analysis mechanism based on a strategy and a model is not established, the functions of zero-common (or zero-dislocation) analysis of the main and standby loops, the analysis of the inherent leakage current of the equipment and the loops and the analysis of the problem of the starting impact load of the motor are not supported, and effective overproof alarm and false alarm cannot be identified.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an analysis method and device for residual current type intelligent monitoring of electrical fire, which can effectively analyze the problems of common zero (or zero dislocation), motor starting impact and the like in the electrical fire leakage fault, avoid the exceeding alarm caused by inherent leakage current of equipment and a loop and improve the alarm accuracy.

The invention is realized by the following steps: the invention discloses a residual current type electric fire intelligent monitoring analysis method, which comprises the following steps:

acquiring the residual current value of the monitored loop, and generating and storing the residual current value of each acquisition time point;

comparing the residual current value with a preset alarm threshold value, if the residual current value exceeds the alarm threshold value, alarming, and simultaneously generating an alarm record;

and intelligently analyzing the monitored loop of which the residual current exceeds the alarm threshold value according to the residual current value monitoring data, the sampling time and the loop characteristic identification, and judging whether the residual current data of the power utilization loop conforms to the characteristics of zero, motor starting impact load or inherent leakage current of equipment and the loop and the like, thereby determining the nature and problem source of the power utilization loop residual current exceeding alarm.

Further, the method also comprises the steps of carrying out effectiveness analysis and preprocessing on a plurality of residual current values in the latest acquisition duration, filtering invalid data and caching effective residual current data;

carrying out effectiveness analysis and pretreatment on a plurality of residual current values in the latest acquisition time length, wherein the effectiveness analysis and pretreatment comprise the following steps:

an electric fire detector comprises one or n sensor nodes, the system caches the acquisition time of each monitoring loop and the corresponding residual current value, such as L (T1, V1), L (T2, V2), L (T3, V3) …, L (Tn, Vn), after current acquisition, the system sequentially reads the residual current value R (Ti, Vi) newly acquired by each sensor node, and compares the acquisition time before and after acquisition, if R (Ti) is less than or equal to L (Ti), R (Ti, Vi) represents the latest acquisition result of the sensor node i, wherein 0< i is less than or equal to n, the acquisition time is judged to be invalid, otherwise, the acquisition time is judged to be valid, and the valid acquisition time of the current residual current acquired by each monitoring loop and the corresponding residual current value are cached and recorded as valid current data for next comparison.

Further, the loop characteristic identification comprises an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop ID and a monitoring loop category.

Acquiring characteristic identification of an alarm or fault monitoring loop, including an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop category and loop description information;

analyzing alarm or fault information data of each level of detectors on the branch circuits aiming at a system provided with a multi-level residual current type electric fire detector, and judging that a fault point is behind a detector set point of a branch circuit if the leakage current of a certain branch circuit accounts for more than or equal to a first set value of the leakage current of the total circuit; if the proportion of the sum of the leakage currents of all the branch circuits to the total circuit leakage current is smaller than or equal to a second set value, judging that a fault point is between a total circuit detector set point and a branch circuit detector set point;

and judging the positioning information of the fault point according to the analysis method.

Further, the intelligent analysis step of the zero-sharing problem in the electrical fire monitoring comprises the following steps:

if a corresponding main/standby loop exists and the current leakage values of the main/standby loops exceed the alarm threshold value and an alarm is generated, judging whether the deviation of the leakage values of the main/standby loops is smaller than or equal to a preset deviation value or not, if so, judging that the residual current of the main/standby loops conforms to a zero-common characteristic, namely judging that the problem source of the residual current alarm is a zero-common problem, automatically filtering the current leakage alarm of the main/standby loops after judging that the residual current of the main/standby loops conforms to the zero-common characteristic, regenerating the alarm record of the zero-common problem and prompting the problem source.

Further, the intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

if the corresponding motor loops exist and loop leakage values of the motor starting time period exceed the alarm threshold value and alarm is generated, whether the alarm time of the motor starting loops is concentrated in a preset time length or not is judged, if yes, the fact that residual current of the loops accords with the characteristics of motor starting impact load is judged, and the problem source of residual current alarm is judged to be the problem of motor starting impact load. And after judging that the residual current of the loop accords with the characteristics of the motor starting impact load, not alarming and automatically filtering the current leakage alarm, and regenerating an alarm record of the motor starting impact load problem and prompting the source of the problem.

Further, the intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following steps:

the leakage current which is continuously present in the monitoring loop within a set time and has a basically fixed measured value is detected; judging whether the leakage current of the power utilization loop meets the following characteristics: in the use process of the set predicted aging time, the leakage current value of the loop is in direct proportion to the time, and the leakage current amplitude is lower than a set value;

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is taken as the inherent leakage current value of the circuit, the inherent leakage current value is excluded from the threshold setting value, and when the value exceeds a certain range, the problem of residual current alarm is judged to be the problem of the inherent leakage current of the equipment and the circuit, which indicates that the circuit or the equipment of the circuit needs to be maintained or replaced.

Further, comparing the residual current value with a preset alarm threshold value, and if the residual current value exceeds the alarm threshold value, giving an alarm, specifically including:

if the loop residual current value of the acquisition time point is greater than the alarm threshold value, recording the alarm starting time; continuously judging whether the loop residual current value of the next acquisition time point is greater than an alarm threshold value, if the continuous n residual currents are greater than the alarm threshold value and the alarm of the loop is not generated in the current alarm record, generating an alarm, and simultaneously recording a loop alarm mark, wherein n is a positive integer, and when the residual current value exceeds the alarm threshold value, identifying the monitoring loop as an alarm state and simultaneously generating an alarm record;

if the residual current value of the loop at the acquisition time point is smaller than the set threshold value and the alarm of the loop is generated in the current alarm record, clearing the current alarm record and recovering the loop alarm mark;

the step of recovering the loop alarm mark is as follows:

acquiring the latest alarm time T0 of the monitoring loop;

acquiring the minimum duration of the normal state of the monitoring circuit through a formula N1-D1, wherein N1 represents the number of times of continuously exceeding a threshold value before an alarm is generated, and D1 represents the interval time of the round trip;

judging whether recovery is performed: and T1 represents the current time, T1- (N1 × D1) and T0 are compared, and if (T1- (N1 × D1)) > T0, the alarm is judged to be not generated again within the specified time, namely the alarm is recovered.

The invention discloses a residual current type electric fire intelligent monitoring analysis device, which comprises a residual current dynamic monitoring module, an intelligent analysis module and a data statistics module,

the residual current dynamic monitoring module is used for acquiring a residual current value of the monitored loop, and generating and storing the residual current value of each acquisition time point;

the intelligent analysis module is used for monitoring and alarming residual current real-time data, and comprises: judging whether residual current exists or not, intelligently analyzing the residual current exceeding an alarm threshold value and a power circuit according to the obtained residual current value, the acquisition time and the circuit characteristic identification of the monitored circuit, judging whether the residual current of the monitored circuit accords with the zero-sharing characteristic of the power circuit in the electric fire monitoring, the motor starting impact load characteristic or the equipment and circuit inherent leakage current characteristic, and if the residual current accords with any one of the characteristics, generating alarm fault information and prompting the root cause of the problem;

the data statistical module is used for carrying out daily, weekly and monthly time-interval statistics on the loop leakage value and realizing trend analysis on the loop leakage value on the basis.

Further, intelligently analyzing residual current exceeding an alarm threshold value and a power circuit, wherein the problem of common zero sharing, the problem of motor starting impact load and the problem of inherent leakage current of equipment and a loop in electrical fire monitoring are intelligently analyzed;

the intelligent analysis step for the zero-sharing problem in the electrical fire monitoring comprises the following steps:

if a corresponding main/standby loop exists and the current leakage values of the main/standby loops exceed the alarm threshold value and an alarm is generated, judging whether the deviation of the leakage values of the main/standby loops is smaller than or equal to a preset deviation value or not, if so, judging that the residual current of the main/standby loops conforms to a zero-sharing characteristic, namely judging that the problem source of the residual current alarm is a zero-sharing problem, automatically filtering the current leakage alarm of the main/standby loops after judging that the residual current of the main/standby loops conforms to the zero-sharing characteristic, regenerating the alarm record of the zero-sharing problem and prompting the problem source;

the intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

if a corresponding motor starting loop exists, the current leakage value of the motor starting loop exceeds an alarm threshold value and an alarm is generated, whether the alarm time of the motor starting loop is concentrated in a preset time length or not is judged, if yes, the residual current of the motor starting loop is judged to accord with the characteristics of a motor starting impact load, namely, the problem source of the residual current alarm is judged to be the problem of the motor starting impact load, and after the residual current of the motor starting loop is judged to accord with the characteristics of the motor starting impact load, the alarm is not given and the current leakage alarm is automatically filtered, the alarm record of the zero-sharing problem is generated again, and the problem source is prompted;

the intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following steps:

the leakage current which is continuously present in the monitoring loop for a certain time and has a basically fixed measured value is detected; the leakage current value of the loop is in direct proportion to the time and has lower amplitude in the set period of time use process;

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is taken as the inherent leakage current value of the circuit, the inherent leakage current value can be excluded from the threshold set value, but when the value exceeds a certain range, the problem of residual current alarm is judged to be the problem of the inherent leakage current of the equipment and the circuit, and the circuit or the equipment of the circuit needs to be maintained or replaced.

The invention has the beneficial effects that: the reasons for the leakage alarm of the electrical fire monitoring system include wiring error, zero (or zero dislocation) of the main and standby loops, impact load of motor start, and inherent leakage current of the equipment and the loops. Both of these problems result in residual currents exceeding the rated value and generating a large number of alarms. The invention mainly aims at three problems of zero (or zero dislocation) of a main loop and a standby loop, motor starting impact load, and inherent leakage current of equipment and a loop, provides an analysis method for intelligently monitoring residual current, and realizes intelligent analysis and fault location of a residual current type electrical fire monitoring loop.

The invention has the functions of monitoring equipment state, judging leakage value and alarming, has the functions of deep analysis such as fault positioning, fault analysis and the like, and comprises basic information of a monitoring loop (including a host, a detector, the position of a power distribution cabinet and a switch cabinet and the like) in the alarming content so as to effectively improve the accuracy of alarming and facilitate operation and maintenance personnel to find positioning problems;

the intelligent analysis system has the advantages of extracting alarm characteristics of the monitoring loop, analyzing and judging the associated loop, matching leakage deviation values, solving the outstanding problems, establishing an intelligent analysis mechanism based on strategies and models, and supporting the intelligent analysis functions of analyzing the common zero (or zero dislocation) of the main loop and the standby loop, starting impact loads of the motor, inherent leakage currents of equipment and loops and the like.

Drawings

FIG. 1 is an overall flow chart of the analytical method of the present invention;

FIG. 2 is a schematic diagram illustrating an intelligent residual current monitoring principle according to the present invention;

FIG. 3 is a second schematic diagram illustrating the intelligent residual current monitoring principle of the present invention;

FIG. 4 is a detailed flow chart of the assay method of the present invention;

FIG. 5 is a graph of the variation of the single-loop residual current (day/week trend statistics) according to the present invention;

FIG. 6 is a comparison of the residual current in the main/standby circuit of the present invention;

FIG. 7 is a schematic diagram of a residual current zero problem determination interface according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 7, the present embodiment provides an analysis method for residual current type intelligent monitoring of electrical fire, including the following steps:

s1) collecting the residual current value of the monitored loop, generating and storing the residual current value of each collecting time point, wherein the monitoring loop is a power line collected by a residual current transformer;

s2) carrying out effectiveness analysis and pretreatment on a plurality of residual current values in the latest acquisition duration, filtering invalid data and caching the residual current values;

carrying out effectiveness analysis and pretreatment on a plurality of residual current values in the latest acquisition time;

the method for processing the residual current data comprises the following specific steps:

judging whether the time is effective: an electrical fire detector includes one or n sensor nodes, and the system buffers the time and remaining current values of each monitoring loop, such as L (T1, V1), L (T2, V2), L (T3, V3) …, L (Tn, Vn). After current collection, the system sequentially reads the residual current value R (Ti, Vi) newly collected by each sensor node, compares the time before and after collection, and judges that the time is invalid if R (Ti) is less than or equal to L (Ti). Where R (Ti, Vi) represents the latest acquisition of sensor node i, where 0< i ≦ n.

Judging whether the residual current alarms: and (3) presetting an alarm threshold value by the system, comparing the residual current value R (Vi) acquired at this time with the alarm threshold value if the time is effective in the judgment, and generating an alarm if the residual current value exceeds the alarm threshold value.

If the effective value of the current amplitude reflected by the filtered frequency domain data is greater than a predetermined first threshold value, it indicates that a residual current exists, or if the current amplitude reflected by the filtered frequency domain data exceeds a predetermined second threshold value, it indicates that a residual current exists.

The effective value is a value with a current amplitude larger than 0, and is usually 0-300 mA under normal conditions. According to the current design standard of the automatic fire alarm system in China, the alarm value of the residual current is preferably 300 mA-500 mA. According to the specification, the system presets a first threshold value and a second threshold value to be 300mA and 500mA respectively. If 300mA is exceeded, this indicates that there is a residual current and that the effective value is greater than a predetermined first threshold value.

And caching and recording the time and the residual current value acquired by each monitoring loop for comparison next time.

S3) processing the residual current of the monitoring loop according to the alarm threshold value to judge whether the residual current exists and whether an alarm is given: comparing the residual current value with a preset alarm threshold value, if the residual current value exceeds the alarm threshold value, alarming, simultaneously generating an alarm record, and executing the step S4);

s4) according to the obtained residual current value, the acquisition time and the loop characteristic identification of the monitored loop, multiple factors and intelligent strategies such as monitoring data, sampling time and the loop characteristic identification are integrated, intelligent analysis is carried out on the residual current exceeding the alarm threshold value and the monitored loop, including intelligent analysis on common zero-sharing problems, motor starting impact loads and equipment and loop inherent leakage currents in electric fire monitoring, and the fact that the electric leakage of the electric loop meets the characteristics of common zero (or zero dislocation), meets the characteristics of the motor starting impact loads or the characteristics of the equipment and loop inherent leakage currents is determined, so that the root cause of the problem is determined.

And after judging whether the residual current of the monitored loop accords with the zero-sharing characteristic of the circuit used in the electrical fire monitoring, the motor starting impact load characteristic or the inherent leakage current characteristic of the equipment and the loop, if the residual current accords with any one of the characteristics, automatically filtering the current leakage alarm corresponding to the monitored loop, regenerating alarm fault information and prompting the root cause of the problem.

The loop characteristic identification comprises an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop ID and a monitoring loop type.

The detection information is intelligently analyzed, possible false alarm information is eliminated or prompted, or faults of an alarm loop are positioned, the total zero, motor impact load and the inherent leakage current of the loop are three major sources of error alarm, the leakage current characteristics of the three are compared respectively, the three can be analyzed and filtered out from the residual current information of the monitored loop, and therefore the fault type is confirmed and the alarm fault information is eliminated, so that data analysis is core, filtering means that the alarm fault information is generated again after analysis, and therefore false alarm and problem prompting are avoided.

The intelligent analysis step of the zero-sharing problem in the electric fire monitoring comprises the following steps:

judging whether the residual current alarms: and (3) presetting an alarm threshold value by the system, comparing the residual current value R (Vi) acquired at this time with the alarm threshold value if the time is effective in the judgment, and generating an alarm if the residual current value exceeds the alarm threshold value.

The current leakage values of the main/standby loops exceed the alarm threshold value (set to be 300 mA-500 mA according to the specification), and an alarm is generated;

the deviation of the leakage value of the main/standby loop is not large (if the deviation is less than or equal to 100mA, the deviation can be set according to actual needs);

and if the main/standby loop meets the characteristics, judging that the problem source of the residual current alarm is a zero-sharing problem.

In the main/standby loop described in this patent, the main loop is a direct power supply loop of the consumer, and the standby loop is a relative main loop, also called an auxiliary loop.

After judging that the residual current of the main and standby circuits conforms to the zero-common (or zero-dislocation) characteristic, automatically filtering the current leakage alarm of the main/standby circuit, regenerating the alarm record of the zero-common (or zero-dislocation) problem, and prompting the source of the problem. For example, "the detector 1 loop 2 and the detector 2 loop 2 of the main machine of the electrical fire disaster have a common zero (or zero dislocation) problem! The leakage values of the two loops respectively reach 552mA/580mA, and both exceed a threshold value of 500 mA! ".

The intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

the current leakage values of the motor starting loops exceed an alarm threshold value (set to be 300 mA-500 mA according to specifications) and generate an alarm;

the alarm time of the motor starting loop is concentrated in a preset time (usually 5-8 seconds, and can be set to other time according to actual conditions);

and if the power utilization circuit meets the characteristics, judging that the source of the problem of residual current alarm is the problem of starting impact load of the motor. And after judging that the residual current of the motor starting loop accords with the characteristics of motor starting impact load, not alarming and automatically filtering the current leakage alarm. For example "the detector circuit 4 of the main unit of an electrical fire has a problem of impact load on the motor start! The leakage values of the loops respectively reach 598mA, and exceed the threshold value of 500 mA! ".

The intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following contents:

the leakage current which is continuously present in the monitoring loop for a certain time and has a basically fixed measured value is detected;

the leakage current value of the loop is in direct proportion to the time and the leakage current amplitude is low in the use process within a preset time period (if the estimated aging time of the equipment is one year, the preset time period refers to one year);

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is used as the inherent leakage current value of the circuit, the inherent leakage current value can be excluded from the threshold setting value, and when the value exceeds a certain range, the circuit or equipment is judged to need maintenance or replacement, namely aging.

The cable or the electric equipment can have inherent leakage current in the use process, the joint of the cable or the electric equipment can be aged over time, and the leakage current can be increased after the joint is aged. This value is to some extent proportional to time and of small magnitude. This can be considered as one of the characteristics of the leakage current inherent in the loop, and is used for judging the root cause of the loop fault alarm.

Further, comparing the residual current value with a preset alarm threshold value, and if the residual current value exceeds the alarm threshold value, giving an alarm, specifically including:

if the loop residual current value of the acquisition time point is greater than the alarm threshold value, recording the alarm starting time; continuously judging whether the loop residual current value of the next acquisition time point is greater than an alarm threshold value, if the continuous n residual currents are greater than the alarm threshold value and the alarm of the loop is not generated in the current alarm record, generating an alarm, and simultaneously recording a loop alarm mark, wherein n is a positive integer, and when the residual current value exceeds the alarm threshold value, identifying the monitoring loop as an alarm state and simultaneously generating an alarm record;

if the residual current value of the loop at the acquisition time point is smaller than the set threshold value and the alarm of the loop is generated in the current alarm record, clearing the current alarm record and recovering the loop alarm mark;

the step of recovering the loop alarm mark is as follows:

acquiring the latest alarm time T0 of the monitoring loop;

acquiring the minimum duration of the normal state of the monitoring circuit through a formula N1-D1, wherein N1 represents the number of times of continuously exceeding a threshold value before an alarm is generated, and D1 represents the interval time of the round trip;

judging whether recovery is performed: and T1 represents the current time, T1- (N1 × D1) and T0 are compared, and if (T1- (N1 × D1)) > T0, the alarm is judged to be not generated again within the specified time, namely the alarm is recovered.

The invention provides on-line monitoring, real-time data analysis and historical statistics of the electrical fire based on the database, and strengthens the intelligent monitoring and fault positioning capabilities of the residual current of the electrical fire monitoring loop through data analysis and processing.

The specific steps of intelligent monitoring and fault location are as follows:

acquiring characteristic identification of an alarm or fault monitoring loop, including an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop category and loop description information;

and aiming at the system provided with the multi-stage residual current type electric fire detector, the alarm or fault information data of each stage of detector on the branch circuit is analyzed. If the proportion of the leakage current of a branch circuit to the leakage current of the total circuit is large (for example, the proportion of the leakage current of a branch circuit to the leakage current of the total circuit is greater than or equal to a first set value, the first set value is set according to actual needs, the first set value can be set to 70%, but is not limited to 70%), and it is determined that the fault point is behind the detector set point of the branch circuit; if the proportion of the sum of the leakage currents of all the branch circuits to the leakage current of the total circuit is smaller (if the proportion of the sum of the leakage currents of all the branch circuits to the leakage current of the total circuit is smaller than or equal to a second set value, the second set value is set according to actual needs, the second set value can be set to be 30 percent, but is not limited to 30 percent), judging that a fault point is between the set point of the detector of the total circuit and the set point of the detector of the branch circuits;

and judging the positioning information of the fault point according to the analysis method.

Based on the above analysis, alarm/fault information is further generated, and an alarm location is determined in the alarm content, for example: the leakage value of the loop 2 of the detector 1 reaches 595mA and exceeds the threshold value of 500mA, and the alarm is carried out on the electrical fire host! [ position: 0.4kV substation P103 cabinet, description: 1# signal main equipment ] ".

The embodiment discloses a residual current type electric fire intelligent monitoring analysis device, which comprises a residual current dynamic monitoring module, an intelligent analysis module and a data statistics module,

the residual current dynamic monitoring module is used for acquiring a residual current value of the monitored loop, and generating and storing the residual current value of each acquisition time point; acquiring a residual current value of a monitored loop to acquire real-time residual current data flowing through a current transformer, wherein the current transformer is used for sensing residual current on a power supply line;

the intelligent analysis module is used for monitoring and alarming residual current real-time data, and comprises: judging whether residual current exists or not, intelligently analyzing the residual current exceeding an alarm threshold value and a power utilization circuit according to multiple factors such as the obtained residual current value, the acquired time and the circuit characteristic identification of the monitored circuit, judging whether the residual current of the monitored circuit accords with the common zero (or zero dislocation) characteristic of the power utilization circuit in the electric fire monitoring, the motor starting impact load characteristic or the inherent leakage current characteristic of equipment and the circuit, and if the residual current accords with any one of the characteristics, generating alarm fault information and prompting the root cause of the problem;

the data statistics module is used for carrying out statistics and analysis on the day, week and month time intervals of the loop leakage value and realizing trend analysis on the loop leakage value on the basis. The method comprises the following steps: dividing a statistical time interval within one day according to a set value (usually 3 minutes), and counting average values and maximum values of different granularities of days, weeks, months and the like according to the statistical time interval; FIG. 5 is a graph of the variation of the single-loop residual current (day/week trend statistics) according to the present invention; FIG. 6 is a comparison of the residual current in the main/standby circuit of the present invention; FIG. 7 is a schematic diagram of a residual current zero problem determination interface according to the present invention.

Further, intelligently analyzing residual current exceeding an alarm threshold value and a power circuit, wherein the problem of common zero sharing, the problem of motor starting impact load and the problem of inherent leakage current of equipment and a loop in electrical fire monitoring are intelligently analyzed;

the intelligent analysis step for the zero-sharing problem in the electrical fire monitoring comprises the following steps:

if a corresponding main/standby loop exists and the current leakage values of the main/standby loops exceed the alarm threshold value and an alarm is generated, judging whether the deviation of the leakage values of the main/standby loops is smaller than or equal to a preset deviation value or not, if so, judging that the residual current of the main/standby loops conforms to a zero-sharing characteristic, namely judging that the problem source of the residual current alarm is a zero-sharing problem, automatically filtering the current leakage alarm of the main/standby loops after judging that the residual current of the main/standby loops conforms to the zero-sharing characteristic, regenerating the alarm record of the zero-sharing problem and prompting the problem source;

the intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

if a corresponding motor starting loop exists, the current leakage value of the motor starting loop exceeds an alarm threshold value and an alarm is generated, whether the alarm time of the motor starting loop is concentrated in a preset time length or not is judged, if yes, the residual current of the motor starting loop is judged to accord with the characteristics of a motor starting impact load, namely, the problem source of the residual current alarm is judged to be the problem of the motor starting impact load, and after the residual current of the motor starting loop is judged to accord with the characteristics of the motor starting impact load, the alarm is not given and the current leakage alarm is automatically filtered, the alarm record of the zero-sharing problem is generated again, and the problem source is prompted;

the intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following steps:

the leakage current which is continuously present in the monitoring loop for a certain time and has a basically fixed measured value is detected; the leakage current value of the loop is in direct proportion to the time and has lower amplitude in the set period of time use process;

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is taken as the inherent leakage current value of the circuit, the inherent leakage current value can be excluded from the threshold set value, but when the value exceeds a certain range, the problem of residual current alarm is judged to be the problem of the inherent leakage current of the equipment and the circuit, and the circuit or the equipment of the circuit needs to be maintained or replaced.

Carry out monitoring alarm to residual current real-time data, include:

if the loop residual current value of the monitoring time point is larger than the alarm threshold value, recording the alarm starting time; and continuously judging whether the loop residual current value of the next monitoring time point is greater than an alarm threshold value, if the continuous n residual currents are greater than the alarm threshold value and the alarm of the loop is not generated in the current alarm record, generating an alarm and simultaneously recording a loop alarm mark, wherein n is a positive integer.

The loop alarm mark is a characteristic value of the monitoring loop in the patent, and identifies whether the monitoring loop is normal, and the values are 0-normal, 1-alarm, 2-early-warning and 3-recovery. And when the residual current value exceeds the alarm threshold value, the monitoring loop is identified to be in an alarm state. Simultaneously, an alarm record is generated, for example: the leakage value of the loop 2 of the detector 1 reaches 595mA and exceeds the threshold value of 500mA, and the alarm is carried out on the electrical fire host! [ position: 0.4kV substation P103 cabinet, description: 1# signal main equipment ] ".

And if the loop residual current value at the monitoring time point is smaller than the set threshold value and the alarm of the loop is generated in the current alarm record, clearing the current alarm record and recovering the loop alarm mark.

The recovery loop alarm mark is used for identifying the monitoring loop which generates the alarm as a normal state when the residual current value is recovered to be below the alarm threshold value. Recovery records are generated simultaneously, for example: the leakage alarm of the main machine of the electrical fire is recovered, the leakage value of the loop 2 of the detector 1 is 261mA, and the normal state is recovered! [ position: 0.4kV substation P202 cabinet, description: 1# signal main equipment ] ".

The recovery loop alarm sign is characterized in that:

① obtaining the latest alarm time T0 of the monitoring loop

② the minimum duration of the normal state of the monitoring circuit (no alarm) is obtained by the formula N1 x D1, where N1 represents the number of consecutive threshold value exceedances before the alarm is generated and D1 represents the interval time of the rounds.

③ judges whether or not the alarm has been recovered, wherein T1 represents the current time, T1- (N1 × D1) and T0 are compared, and if (T1- (N1 × D1)) > T0, the alarm is judged to have not been generated again within the specified time, namely the alarm has been recovered.

Compared with the prior art, the invention has the advantages of conventional monitoring of the change condition of the residual current in the electric circuit and the alarm function, and also has the advantages of further strategy analysis and alarm positioning on the electric leakage alarm generated by the problem of zero (or zero dislocation) of the electric circuit and the problem of the starting impact load of the motor. The invention processes the residual current of the monitoring loop according to the alarm threshold value to judge whether the residual current exists and whether the alarm is given. The method comprises the steps of carrying out intelligent analysis on the common zero-sharing problem, motor starting impact load, equipment and loop inherent leakage current in electrical fire monitoring on residual current and power utilization circuits exceeding threshold values, comprehensively monitoring data, sampling time, loop characteristic identification and other multiple factors and intelligent strategies, and determining that the electric leakage of the power utilization circuits accords with the common zero-sharing (or zero dislocation) characteristic, the motor starting impact load characteristic or the equipment and loop inherent leakage current characteristic, thereby determining the root cause of the problem.

The invention has the functions of monitoring equipment state, judging leakage value and alarming, has the functions of deep analysis such as fault positioning, fault analysis and the like, and comprises basic information of a monitoring loop (including a host, a detector, the position of a power distribution cabinet and a switch cabinet and the like) in the alarming content so as to effectively improve the accuracy of alarming and facilitate operation and maintenance personnel to find positioning problems; the invention has the algorithms of monitoring loop alarm characteristic extraction, associated loop analysis and judgment and electric leakage deviation value matching, solves the outstanding problems, establishes an intelligent analysis mechanism based on a strategy and a model, and supports the intelligent analysis functions of the problems of zero (or zero dislocation) analysis of the main loop and the standby loop, the motor starting impact load, the inherent leakage current of equipment and the loop and the like.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. A residual current type electric fire intelligent monitoring analysis method is characterized by comprising the following steps:

acquiring the residual current value of the monitored loop, and generating and storing the residual current value of each acquisition time point;

comparing the residual current value with a preset alarm threshold value, if the residual current value exceeds the alarm threshold value, alarming, and simultaneously generating an alarm record;

and intelligently analyzing the monitored loop of which the residual current exceeds the alarm threshold value according to the residual current value monitoring data, the sampling time and the loop characteristic identification, and judging whether the residual current data of the power utilization loop conforms to the characteristics of zero, motor starting impact load or inherent leakage current of equipment and the loop and the like, thereby determining the nature and problem source of the power utilization loop residual current exceeding alarm.

2. The method of claim 1, wherein: the method also comprises the steps of carrying out effectiveness analysis and preprocessing on a plurality of residual current values in the latest acquisition duration, filtering invalid data and caching effective residual current data;

carrying out effectiveness analysis and pretreatment on a plurality of residual current values in the latest acquisition time length, wherein the effectiveness analysis and pretreatment comprise the following steps:

an electric fire detector comprises one or n sensor nodes, the system caches the acquisition time of each monitoring loop and the corresponding residual current value, such as L (T1, V1), L (T2, V2), L (T3, V3) …, L (Tn, Vn), after current acquisition, the system sequentially reads the residual current value R (Ti, Vi) newly acquired by each sensor node, and compares the acquisition time before and after acquisition, if R (Ti) is less than or equal to L (Ti), R (Ti, Vi) represents the latest acquisition result of the sensor node i, wherein 0< i is less than or equal to n, the acquisition time is judged to be invalid, otherwise, the acquisition time is judged to be valid, and the valid acquisition time of the current residual current acquired by each monitoring loop and the corresponding residual current value are cached and recorded as valid current data for next comparison.

3. The method of claim 1, wherein: the loop characteristic identification comprises an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop ID and a monitoring loop category.

4. The method of claim 1, wherein: acquiring characteristic identification of an alarm or fault monitoring loop, including an acquisition point ID, an electrical fire monitoring host ID, an electrical fire detector ID, a monitoring loop category and loop description information;

analyzing alarm or fault information data of each level of detectors on the branch circuits aiming at a system provided with a multi-level residual current type electric fire detector, and judging that a fault point is behind a detector set point of a branch circuit if the leakage current of a certain branch circuit accounts for more than or equal to a first set value of the leakage current of the total circuit; if the proportion of the sum of the leakage currents of all the branch circuits to the total circuit leakage current is smaller than or equal to a second set value, judging that a fault point is between a total circuit detector set point and a branch circuit detector set point;

and judging the positioning information of the fault point according to the analysis method.

5. The method of claim 1, wherein: the intelligent analysis step for the zero-sharing problem in the electrical fire monitoring comprises the following steps:

if a corresponding main/standby loop exists and the current leakage values of the main/standby loops exceed the alarm threshold value and an alarm is generated, judging whether the deviation of the leakage values of the main/standby loops is smaller than or equal to a preset deviation value or not, if so, judging that the residual current of the main/standby loops conforms to a zero-common characteristic, namely judging that the problem source of the residual current alarm is a zero-common problem, automatically filtering the current leakage alarm of the main/standby loops after judging that the residual current of the main/standby loops conforms to the zero-common characteristic, regenerating the alarm record of the zero-common problem and prompting the problem source.

6. The method of claim 1, wherein: the intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

if the corresponding motor loops exist and loop leakage values of the motor starting time period exceed the alarm threshold value and alarm is generated, whether the alarm time of the motor starting loops is concentrated in a preset time length or not is judged, if yes, the fact that residual current of the loops accords with the characteristics of motor starting impact load is judged, and the problem source of residual current alarm is judged to be the problem of motor starting impact load. And after judging that the residual current of the loop accords with the characteristics of the motor starting impact load, not alarming and automatically filtering the current leakage alarm, and regenerating an alarm record of the motor starting impact load problem and prompting the source of the problem.

7. The method of claim 1, wherein: the intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following steps:

the leakage current which is continuously present in the monitoring loop within a set time and has a basically fixed measured value is detected; judging whether the leakage current of the power utilization loop meets the following characteristics: in the use process of the set predicted aging time, the leakage current value of the loop is in direct proportion to the time, and the leakage current amplitude is lower than a set value;

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is taken as the inherent leakage current value of the circuit, the inherent leakage current value is excluded from the threshold setting value, and when the value exceeds a certain range, the problem of residual current alarm is judged to be the problem of the inherent leakage current of the equipment and the circuit, which indicates that the circuit or the equipment of the circuit needs to be maintained or replaced.

8. The method of claim 1, wherein: comparing the residual current value with a preset alarm threshold value, and if the residual current value exceeds the alarm threshold value, giving an alarm, specifically comprising:

if the loop residual current value of the acquisition time point is greater than the alarm threshold value, recording the alarm starting time; continuously judging whether the loop residual current value of the next acquisition time point is greater than an alarm threshold value, if the continuous n residual currents are greater than the alarm threshold value and the alarm of the loop is not generated in the current alarm record, generating an alarm, and simultaneously recording a loop alarm mark, wherein n is a positive integer, and when the residual current value exceeds the alarm threshold value, identifying the monitoring loop as an alarm state and simultaneously generating an alarm record;

if the residual current value of the loop at the acquisition time point is smaller than the set threshold value and the alarm of the loop is generated in the current alarm record, clearing the current alarm record and recovering the loop alarm mark;

the step of recovering the loop alarm mark is as follows:

acquiring the latest alarm time T0 of the monitoring loop;

acquiring the minimum duration of the normal state of the monitoring circuit through a formula N1-D1, wherein N1 represents the number of times of continuously exceeding a threshold value before an alarm is generated, and D1 represents the interval time of the round trip;

judging whether recovery is performed: and T1 represents the current time, T1- (N1 × D1) and T0 are compared, and if (T1- (N1 × D1)) > T0, the alarm is judged to be not generated again within the specified time, namely the alarm is recovered.

9. The utility model provides a residual current formula electric fire intelligent monitoring's analytical equipment which characterized in that: comprises a residual current dynamic monitoring module, an intelligent analysis module and a data statistics module,

the residual current dynamic monitoring module is used for acquiring a residual current value of the monitored loop, and generating and storing the residual current value of each acquisition time point;

the intelligent analysis module is used for monitoring and alarming residual current real-time data, and comprises: judging whether residual current exists or not, intelligently analyzing the residual current exceeding an alarm threshold value and a power circuit according to the obtained residual current value, the acquisition time and the circuit characteristic identification of the monitored circuit, judging whether the residual current of the monitored circuit accords with the zero-sharing characteristic of the power circuit in the electric fire monitoring, the motor starting impact load characteristic or the equipment and circuit inherent leakage current characteristic, and if the residual current accords with any one of the characteristics, generating alarm fault information and prompting the root cause of the problem;

the data statistical module is used for carrying out daily, weekly and monthly time-interval statistics on the loop leakage value and realizing trend analysis on the loop leakage value on the basis.

10. The apparatus of claim 9, wherein: intelligently analyzing residual current exceeding an alarm threshold value and a power line, wherein the problem of common zero, the problem of motor starting impact load and the problem of inherent leakage current of equipment and a loop in electrical fire monitoring are intelligently analyzed;

the intelligent analysis step for the zero-sharing problem in the electrical fire monitoring comprises the following steps:

if a corresponding main/standby loop exists and the current leakage values of the main/standby loops exceed the alarm threshold value and an alarm is generated, judging whether the deviation of the leakage values of the main/standby loops is smaller than or equal to a preset deviation value or not, if so, judging that the residual current of the main/standby loops conforms to a zero-sharing characteristic, namely judging that the problem source of the residual current alarm is a zero-sharing problem, automatically filtering the current leakage alarm of the main/standby loops after judging that the residual current of the main/standby loops conforms to the zero-sharing characteristic, regenerating the alarm record of the zero-sharing problem and prompting the problem source;

the intelligent analysis step of the motor starting impact load in the electrical fire monitoring comprises the following steps:

if a corresponding motor starting loop exists, the current leakage value of the motor starting loop exceeds an alarm threshold value and an alarm is generated, whether the alarm time of the motor starting loop is concentrated in a preset time length or not is judged, if yes, the residual current of the motor starting loop is judged to accord with the characteristics of a motor starting impact load, namely, the problem source of the residual current alarm is judged to be the problem of the motor starting impact load, and after the residual current of the motor starting loop is judged to accord with the characteristics of the motor starting impact load, the alarm is not given and the current leakage alarm is automatically filtered, the alarm record of the zero-sharing problem is generated again, and the problem source is prompted;

the intelligent analysis content of the intrinsic leakage current of the equipment and the loop comprises the following steps:

the leakage current which is continuously present in the monitoring loop for a certain time and has a basically fixed measured value is detected; the leakage current value of the loop is in direct proportion to the time and has lower amplitude in the set period of time use process;

if the leakage current of the circuit meets the characteristics, the average value measured in the last period of time is taken as the inherent leakage current value of the circuit, the inherent leakage current value can be excluded from the threshold set value, but when the value exceeds a certain range, the problem of residual current alarm is judged to be the problem of the inherent leakage current of the equipment and the circuit, and the circuit or the equipment of the circuit needs to be maintained or replaced.

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